Myogenic and neurogenic differentiation of human tooth germ stem cells (hTGSCs) are regulated by pluronic block copolymers

Stem cells with high proliferation, self-renewal and differentiation capacities are promising for tissue engineering approaches. Among stem cells, human tooth germ stem cells (hTGSCs) having mesenchymal stem cell characteristics are highly proliferative and able to differentiate into several cell lineages. Researchers have recently focused on transplanting stem cells with bioconductive and/or bioinductive materials that can provide cell commitment to the desired cell lineages. In the present study, effects of pluronic block copolymers (F68, F127 and P85) on in vitro myo- and neurogenic differentiation of human tooth germ stem cells (hTGSCs) were investigated. As P85 was found to exert considerable toxicity to hTGSCs even at low concentrations, it was not evaluated for further differentiation experiments. Immunocytochemical analysis, gene and protein expression studies revealed that while F68 treatment increased lineage-specific gene expression in both myo- and neuro-genically differentiated cells, F127 did not result in any remarkable difference compared to cells treated with differentiation medium. Subsequent studies are required to explore the exact mechanisms of how F68 increases the myogenic and neurogenic differentiation of hTGSCs. The present work indicates that pluronic F68 might be used in functional skeletal and neural tissue engineering applications.     

Protein-based block copolymers

Advances in genetic engineering have led to the synthesis of protein-based block copolymers with control of chemistry and molecular weight, resulting in unique physical and biological properties. The benefits from incorporating peptide blocks into copolymer designs arise from the fundamental properties of proteins to adopt ordered conformations and to undergo self-assembly, providing control over structure formation at various length scales when compared to conventional block copolymers. This review covers the synthesis, structure, assembly, properties, and applications of protein-based block copolymers.     

Bacterial synthesis of PHA block copolymers

Polyhydroxyalkanoates (PHA) containing block copolymers were synthesized in Cupriavidus necator using periodic substrate addition. Poly(3-hydroxybutyrate) (PHB) segments were formed during fructose utilization. Pulse feeds of pentanoic acid resulted in the synthesis of 3-hydroxyvalerate monomers, forming poly(3-hydroxybutyrate-co-3-hydroxyvalerate) (PHBV) random copolymer. PHA synthesis was controlled using analysis of oxygen uptake and carbon evolution rates from the bioreactor off-gas. A combination of characterization techniques applied to the polymer batches strongly suggests the presence of block copolymers: (i) Thermodynamically stable polymer samples obtained by fractionation and analyzed by differential scanning calorimetry (DSC) and nuclear magnetic resonance spectroscopy (NMR) indicate that some fractions, representing approximately 30% of the total polymer sample, exhibit melting characteristics and nearest-neighbor statistics indicative of block copolymers, (ii) preliminary rheology experiments indicate additional mesophase transitions only found in block copolymer materials, (iii) dynamic mechanical analysis shows extension of the rubbery plateaus in block copolymer samples, and (iv) uniaxial extension tests result in differences in mechanical properties (modulus and elongation at failure) expected of similarly prepared block copolymer and single polymer type materials.     

"Clickable" PEG-dendritic block copolymers

Three generations of azido-terminated PEG-dendritic block copolymers have been synthesized and completely characterized by NMR and MALDI-TOF. A radial decrease of density, leading to more mobile protons at the outermost periphery, and an increasingly higher compactness of the core with generation have been determined by T(1) and T(2) relaxation time studies. The efficient surface decoration of these dendritic polymers by means of click chemistry has been demonstrated by the incorporation of unprotected carbohydrate units in very good to excellent yields. The reaction proceeds at room temperature, under aqueous conditions, and requires just catalytic amounts of Cu. The modified block copolymers are conveniently purified by ultrafiltration. The glycodendrimers functionalized with alpha-mannose form aggregates with concanavalin A as determined by absorbance experiments at 400 nm. This aggregation ability increases with generation.     

Poly(ethylene glycol) block copolymers

The ubiquitous use of poly(ethylene glycol) in the biomaterials field has also boosted the research activity in the chemical derivatization of this polymer. We focused our interest on the preparation of tailor-made poly(ethylene glycol)-based structures and on the study of structure-activity relationships for its functionalization, as preliminary steps for the preparation of smart functional materials. More specifically, amphiphilic and cationic block copolymers were prepared for prospective use in the preparation of self-assembled carriers, and Michael-type addition of thiols onto acrylates was studied as a model for end-group reaction leading to hydrogel formation.     

Genetic engineering of stimuli-sensitive silkelastin-like protein block copolymers

Differentially charged analogues of block copolymers containing repeating sequences from silk (GAGAGS) and elastin (GVGVP) were synthesized using genetic engineering techniques by replacing a valine residue with glutamic acid. The sensitivity to pH and temperature was examined at various polymer concentrations, ionic strengths, and polymer lengths. The polymers transitioned from soluble to precipitate state over narrow temperature ranges. The transition temperature T(t) (the temperature at which half-maximal spectrophotometric absorption was observed) increased with increasing pH up to pH 7.0 and leveled off above this value for the Glu-containing polymer (17E)(11). T(t) was independent of pH for the Val-containing polymer (17V)(11). It decreased with increasing ionic strength, polymer concentration, and polymer length for both polymers. These results suggest that by substituting charged amino acids for neutral amino acids at strategic locations in the polymer backbone and by control of the length of silkelastin-like block copolymers using genetic engineering techniques, it is possible to precisely control sensitivity to pH, temperature, and ionic strength.     

Self-assembly and photo-cross-linking of eight-armed PEG-PTMC star block copolymers

Eight-armed poly(ethylene glycol)-poly(trimethylene carbonate) star block copolymers (PEG-(PTMC)(8)) linked by a carbamate group between the PEG core and the PTMC blocks were synthesized by the metal-free, HCl-catalyzed ring-opening polymerization of trimethylene carbonate using an amine-terminated eight-armed star PEG in dichloromethane. Although dye solubilization experiments, nuclear magnetic resonance spectroscopy, and dynamic light scattering clearly indicated the presence of aggregates in aqueous dispersions of the copolymers, no physical gelation was observed up to high concentrations. PEG-(PTMC(9))(8) was end-group-functionalized using acryloyl chloride and photopolymerized in the presence of Irgacure 2959. When dilute aqueous dispersions of PEG-(PTMC(9))(8)-Acr were UV irradiated, chemically cross-linked PEG-PTMC nanoparticles were obtained, whereas irradiation of more concentrated PEG-(PTMC(9))(8)-Acr dispersions resulted in the formation of photo-cross-linked hydrogels. Their good mechanical properties and high stability against hydrolytic degradation make photo-cross-linked PEG-PTMC hydrogels interesting for biomedical applications such as matrices for tissue engineering and controlled drug delivery systems.     

Ionophoric actions of avenaciolide on mitochondrial cations

Avenaciolide produces an initial stimulation of mitochondrial respiration followed at high doses of the drug by a decline in respiration to less than the unstimulated rate; under these conditions the mitochondria are insensitive to ADP and to uncoupler. At lower avenaciolide concentrations followed by ADP there is a sustained acceleration of respiration which is sensitive to EDTA and oligomycin, pointing to the existence of a Mg-requiring ATPase.Spectrophotometric tests with bromthymol blue and fluorimetry show a similarity between the responses to avenaciolide and divalent cations.Mitochondrial contents of substrate anions and cations are altered by avenaciolide; the extent of the changes depend on the level of the drug used and also on the composition of the medium. If K⁺ is present with an energy source, the uptake of K⁺ at the start of an incubation is enhanced by avenaciolide when supplied at less than 25–30 nmole/mg protein, and the K⁺ gain is accompanied by an uptake of substrate anion; at higher concentrations of avenaciolide the direction of flow is reversed with loss of K⁺, divalent cations, and substrate anions. In potassium-free media, or in the absence of energy only losses of ions are found.Addition of avenaciolide to mitochondria onto which [¹⁴C]octyl malonate had previously been adsorbed results in a discharge of the labeled compound.     

Preparation of shell cross-linked nano-objects from hybrid-peptide block copolymers

Supramolecular structures formed by self-assembly of diblock copolymers in solution are stable over restricted environmental conditions: concentration, temperature, pH, or ion strength among others. To enlarge their domain of application, it appears necessary to develop stabilization strategies. We report here different strategies to stabilize the shell of micelles formed by self-assembly of amphiphilic polydiene-b-polypeptide diblock copolymers. For this purpose, covalent bonds can be formed between either amine or carboxylic acid groups distributed along the soluble peptide block and a cross-linking agent that contains respectively aldehyde or amine functions. Shell stabilization affords systems with unique properties that combine three main advantages: shape persistence, control of the porosity, and stimuli-responsive behavior. The covalent capture of such macromolecular objects has been studied by light scattering, AFM, and conductimetry measurements.     

Investigating the structure-property relationship of bacterial PHA block copolymers

Mechanical testing of solvent cast films consisting of short-chain-length (SCL) polyhydroxyalkanoate (PHA) films suggested that films consisting of block copolymers retained more elasticity over time with respect to films of similar random copolymers of comparable composition. Two experimental techniques, wide angle X-ray scattering (WAXS) and uniaxial extension, were used to quantitatively investigate the structure-property relationship of bacterially synthesized PHA block copolymers of poly(3-hydroxybutyrate) (PHB) homopolymer and poly(3-hydroxybutyrate-co-3-hydroxyvalerate) random copolymer (PHBV) segments. Uniaxial testing experiments yielded the Young's modulus, ultimate tensile strength, and the elongation until fracture of the films. Percent crystallinity was determined by deconvolution of amorphous and crystalline scattering peaks obtained from WAXS. Two PHBV films containing either 8% 3-hydroxyvalerate monomer (3HV) or 29% 3HV exhibited a quick transition to brittle behavior, decreasing to less than 20% percent elongation at fracture within a few days after annealing. Conversely, the block copolymer samples remained higher than 100% elongation at fracture a full 3 months after annealing. Because block copolymers covalently link polymers that would otherwise form thermodynamically separate phases, the rates and degrees of crystallization of the block copolymers are less than the random copolymer samples. These differences translate into materials that extend the property space of biologically synthesized SCL PHA.     

The immunomodulating properties and antitumor activity of block copolymers of ethylene oxide and propylene oxide (proxanols)

Influence of block copolymers of ethylene and propylene oxides (proxanols) on the human natural killer activity was studied. Proxanols had no effect on the lymphocytes viability and increased their cytotoxic activity against target cells K 562 in vitro. Certain antitumor properties of proxanols were demonstrated in vivo (especially for ascitic tumors). The proxanols activity was chiefly determined by the membranotropic properties of its main polymer chain.     

Ionophoric activity of truncated gramicidin A analogue in phospholipid bilayers and mitochondrial and erythrocyte membranes

Ionophoric activities of an N-terminus truncated gramicidin A (gA) analogue (mini-gramicidin) and its covalent dimer were studied in planar bilayer phospholipid membranes (BLM) using macroscopic current measurements (at high concentrations of the peptides) and single-channel recordings. As with gA-induced currents, mini-gramicidin-stimulated macroscopic currents through BLM underwent sensitized photoinactivation, i.e. were suppressed after irradiation with visible light in the presence of a photosensitizer generating singlet oxygen. The sensitivity of the tested compounds to photoinactivation descended in the following order: minigramicidin dimer > mini-gramicidin monomer > gA. The data from single-channel measurements and kinetic analysis of flash-induced photoinactivation obtained at different levels of macroscopic currents suggest that mini-gramicidin and its covalent dimer induce a variety of conducting states; their ratio depends on membrane thickness. Analysis of natural (mitochondrial and erythrocyte) membranes established that ionophoric activities of mini-gramicidin and its covalent dimer depend essentially on the membrane type.     

Effects of nanoparticles on the compatibility of PEO-PMMA block copolymers

The compatibility of six kinds of designed poly(ethylene oxide)-block-poly(methyl methacrylate) (PEO-b-PMMA) copolymers was studied at 270, 298 and 400 K via mesoscopic modeling. The values of the order parameters depended on both the structures of the block copolymers and the simulation temperature, while the values of the order parameters of the long chains were higher than those of the short ones; temperature had a more obvious effect on long chains than on the short ones. Plain copolymers doped with poly(ethylene oxide) (PEO) or poly(methyl methacrylate) (PMMA) homopolymer showed different order parameter values. When a triblock copolymer had the same component at both ends and was doped with one of its component polymers as a homopolymer (such as A5B6A5 doped with B6 or A5 homopolymer), the value of its order parameter depended on the simulation temperature. The highest order parameter values were observed for A5B6A5 doped with B6 at 400 K and for A5B6A5 doped with A5 at 270 K. A study of copolymers doped with nanoparticles showed that the mesoscopic phase was influenced by not only the properties of the nanoparticles, such as the size and density, but also the compositions of the copolymers. Increasing the size of the nanoparticles used as a dopant had the most significant effect on the phase morphologies of the copolymers.     

Reversible hydrogels from self-assembling genetically engineered protein block copolymers

A series of triblock protein copolymers composed of a central water-soluble polyelectrolyte segment flanked by two coiled-coil domains was synthesized by genetic engineering methods. The copolymers self-assembled into reversible hydrogels in response to changes in temperature, pH, and the presence or absence of denaturating agent (guanidine hydrochloride, GdnHCl). Hydrogel formation was concentration-dependent, and the concentration needed for hydrogel formation correlated with the oligomerization state of the coiled-coil domains in the protein copolymers. The morphology of the hydrogels, as determined by scanning electron microscopy (SEM), indicated the presence of porous interconnected networks. The thermal stabilities and self-assembling properties of the protein copolymers were successfully controlled by manipulating the amino acid sequences of the coiled-coil domains. The stimuli responsiveness and reversibility of the hydrogel self-assembly suggest that these protein copolymers may have potential in biomedical applications.     

Hybrid materials from amphiphilic block copolymers and membrane proteins

Self-assembly of reactive amphiphilic block copolymers is used to prepare nanostructured hydrogels with exceptional permeability properties, vesicular structures and planar, freestanding membranes in aqueous solution. Although the underlying block copolymer membranes are two-three-fold thicker than conventional lipid bilayers, they can be regarded as mimetic of biological membranes and can be used as a matrix for membrane-spanning proteins. Surprisingly, the proteins remain functional, despite the extreme thickness of the membranes and even after polymerization of the reactive block copolymers. The unique combination of block copolymers with membrane proteins allows the preparation of mechanically stable, defect-free membranes and nanocapsules that have highly selective permeability and/or specific recognition sites. This is documented by some representative examples.     

Novel synthesis and characterization of bioconjugate block copolymers having oligonucleotides

Novel and efficient synthesis of polymers terminated with nucleotides via the phosphoramidite method has been developed. A hydroxyl-terminated polymer was converted into a polymer capped with a nucleotide in three steps, where the conversion of the reactions was very high, almost 100%. By repetition of this synthetic method, a block copolymer composed of a synthetic polymer, polystyrene, and biological oligonucleotides with thymidine units has been successfully synthesized. A microphase-separated structure of this block copolymer was observed by both transmission electron microscopy and small-angle X-ray scattering, and a cylindrical structure was confirmed.     

Synthesis and ordered structure of amphipatic block copolymers with a saccharide and a peptide block

Amphipatic block copolymers (OβEb) with a hydrophilic saccharide block and a hydrophobic polypeptide block were synthesized. In these copolymers the saccharide block is the glyco-amino acid Oβ from ovomucoid and the peptide block (Eb) is a poly(γ-benzyl-L -glutamate) block. Copolymers OβEb exhibit, in the solid state and in Me₂SO concentrated solutions, mesomorphic lamellar structures where the polypeptide chains are in an α-helical conformation. Depending on the molecular weight of the polypeptide block, three types of lamellar structures are obtained, and they differ by the mode of organization of the polypeptide chains in their lamellae and by the T or Y conformation of the saccharide block.